Modeling Weight Loss and Chlorogenic Acids Content in Coffee

Nov 4, 2010 - Roasting is a key step in the production of a high-quality coffee. Roasting degree is directly related to coffee chemical composition an...
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J. Agric. Food Chem. 2010, 58, 12238–12243 DOI:10.1021/jf102110u

Modeling Weight Loss and Chlorogenic Acids Content in Coffee during Roasting DANIEL PERRONE,† RAUL DONANGELO,‡ CARMEN M. DONANGELO,† AND ADRIANA FARAH*,† †

Laborato´rio de Bioquı´ mica Nutricional e de Alimentos, Universidade Federal do Rio de Janeiro, Instituto de Quı´ mica, Departamento de Bioquı´ mica, Ilha do Fund~ao, CT bloco A, 21949-900 Rio de Janeiro, RJ, Brazil, and ‡Instituto de Fı´ sica, Universidade Federal do Rio de Janeiro, Ilha do Fund~ao, CT bloco A, C.P. 68.528, 21941-972 Rio de Janeiro, RJ, Brazil

Roasting is a key step in the production of a high-quality coffee. Roasting degree is directly related to coffee chemical composition and may be determined objectively by weight loss after roasting. Chlorogenic acids (CGA) are thermally labile phenolic compounds that play an important role in the final cup quality and health benefits of coffee. Considering the interest in finding a reliable method to predict weight loss and CGA content in coffee, models have been developed to estimate these parameters during roasting. Weight loss was successfully modeled (r = 0.99) independent of the instant temperature. CGA degradation followed first-order Arrhenius-compliant kinetic models with good predictability (r = 0.98), especially for light to moderately dark samples. In both cases distinct models for Coffea arabica and Coffea canephora were calculated, because of differences in chemical composition and cell wall structure between these species. The proposed models may become important predictive tools in the coffee industry. KEYWORDS: Modeling; chlorogenic acids; weight loss; coffee roasting

INTRODUCTION

The coffee industry is one of the most economically important food industries in the world. Roasting is a key step for the production of high-quality roast and ground coffees, because it is during the roasting process that the desired color, aroma, and taste of the beans are produced (1, 2). Roasting is a process depending on time and temperature, in which physical and chemical changes are induced by pyrolysis (3). The chemical composition of roasted coffee is directly related to the roasting degree and depends upon the characteristics of the coffee bean as well as the roasting conditions (4). The roasting degree may be determined by the color of the beans, weight loss, flavor and aroma development, or chemical changes of certain components (5). The use of sophisticated techniques, such as laser mass spectroscopy (6) and gas chromatography (4), has been proposed as possible, although expensive, alternative tools for the online control of the roasting process. In the industry, however, to deliver consistent quality one often trusts an experienced roaster who, on the basis of his expertise and senses, uses a subjective and empirical indicator such as visual color of the beans to control the process (6). Alternatively, measurement of the beans’ weight loss during the roasting process could be a simple and low-cost nonsubjective way to assess roasting degree. However, because it cannot be performed online during roasting, it cannot be directly used as a process control parameter. *Corresponding author (phone þ552125627352; fax þ552125628213; e-mail [email protected]).

pubs.acs.org/JAFC

Published on Web 11/04/2010

On the other hand, modeling weight loss may be considered a useful tool to predict adequate process parameters to obtain, on a regular basis, coffee beans with the desired roasting degree. Moreover, such models would have implications in the assessment of the thermally induced changes in various natural coffee components and contaminants, which are degraded (chlorogenic acids, trigonelline, bioactive amines, mycotoxins) (7-10) or formed (chlorogenic acid lactones, niacin, melanoidins, polycyclic aromatic hydrocarbons) (7, 8, 11, 12) during coffee roasting. Chlorogenic acids (CGA) are a class of phenolic compounds formed by the esterification of certain trans-cinnamic acids with (-)-quinic acid. The main subgroups of chlorogenic acid isomers in coffee are the caffeoylquinic acids (CQA), feruloylquinic acids (FQA), and dicaffeoylquinic acids (diCQA) (13), which together account for 98% of total CGA composition (14). CGA represent 4-12% of green coffee constituents in mass and contribute to the final acidity, astringency, bitterness, and overall cup quality of the beverage (1, 15, 16). During roasting, CGA is lost as a consequence of the thermal breakage of carbon-carbon covalent bonds, resulting in isomerization in the initial roasting stages and epimerization, lactonization, and degradation in the later stages (14, 15). Several beneficial health effects have been attributed to CGA and their lactones, such as antioxidant, antimicrobial, antidiabetes, hepatoprotective, and antimutagenic activities (16-18). Despite the relevance of measuring CGA isomers in coffee, most studies investigating CGA content have focused exclusively on 5-CQA, the most abundant CGA isomer in coffee, for which commercial standards are available. Although the Folin-Ciocalteu

© 2010 American Chemical Society

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J. Agric. Food Chem., Vol. 58, No. 23, 2010

assay for total phenolics could be used for an alternative measurement of CGA content in coffee, it usually leads to an overestimation because other natural coffee reductant components are known to interfere in the assay (19). In addition, as CGA comprise a large class of compounds (14, 15), it is usually difficult and timeconsuming to obtain a satisfactory chromatographic separation of all CGA compounds. Therefore, the possibility of predicting coffee CGA content during roasting is of great interest. In the past two decades, a series of independent studies dealing with the effect of roasting on weight loss and CGA content in coffee have been performed by our research group (1, 7, 14-16, 20-22). During these studies, the existence of a relatively regular behavior pattern in relation to the kinetics of CGA degradation was noted. Considering the potential importance of finding a reliable method to estimate weight loss and CGA content in coffee, the objective of this study was to develop models to predict these parameters during roasting.

Database. The considered database consisted of two coffee samples (Coffea canephora and Coffea arabica, both from Guaxupe´ , Minas Gerais, Brazil), which were roasted at four different temperatures during six different time periods, totaling 48 experiments. C. arabica and C. canephora samples were separated into two sets of experiments, and distinct model parameters were determined for each coffee species. To validate the models, experiments were further randomly divided into a learning database (total of 32 experiments) to compute model parameters and a validation database (total of 16 experiments) to test the prediction ability of the models. The database included CGA data on both green and roasted samples as well as weight loss data during the roasting process. Roasting. All coffee samples (30 g) were roasted in a commercial spouted bed roaster (i-Roast2 model 40011, Hearthware Home Products, Gurnee, IL) operating at set temperatures of 170, 180, 190, or 200 °C for 4, 5, 6, 7, 8, or 9 min, followed by a fixed 4 min air-cooling period. A thermometer probe continuously monitored the air temperature inside the roasting chamber, which was recorded at 1 min intervals. The repeatability of the roasting process was evaluated in a six-replicate experiment, where the coffee sample was roasted at 170 °C for 6 min. The obtained coefficient of variation for percent weight loss was very low (0.6%). Therefore, we found it appropriate to roast coffee beans once in each condition. The color of coffee samples was determined by comparison with color disks from the “Roasting Color Classification System” (Agtron-SCAA, Reno, NV; 1995), following the standards used by the Brazilian Coffee Industries Association (ABIC). Weight Loss. The percent weight loss (%WL) of coffee beans after each roasting condition was calculated using the equation ðWbr - War Þ  100 Wbr

the roasting temperature. In this simplest model one can assume d½ΔmðTðtÞÞ ¼ a dt

ð2Þ

where Δm(T(t)) is the weight loss (%) at a certain time t (min) when coffee is being roasted at a temperature of T (°C) and a is a constant. After integration of eq 3 on the time interval between 0 and tf, which corresponds to the final roasting time (tR) plus the 4 min standard cooling period (tf = tR þ 40 ), we obtain Z Δm ¼

tf

a dt ¼ a½tf 

ð3Þ

0

From the relationship above we may write the variance associated with the parameter value a as f ðaÞ ¼

i¼n expt X

½ðtf Þa - Δm2

ð4Þ

i¼1

where nexpt is the number of measurements performed. From minimization of this variance we obtain an estimate for the value of a:

MATERIALS AND METHODS

%WL ¼

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i¼n expt X

a ¼

Δmðtf Þ ðtf Þ=

i¼1

i¼n expt X

ðtf Þ2

ð5Þ

i¼1

Substituting this value of a into eq 3, the weight loss predicted by the model can be finally obtained. Model 2: Linear Temperature Dependence. This version of the model hypothesizes that the weight loss rate is linearly dependent on the roasting temperature: d½ΔmðTðtÞÞ ¼ a þ bTðtÞ dt

ð6Þ

where Δm(T(t)) is the weight loss (%) at a certain time t (min) when coffee is being roasted at a temperature of T (°C) and a and b are constants. After integration, this equation becomes Z

tf

Δm ¼

Z

tf

½a þ bTðtÞ dt ¼ a½tf  þ b

0

TðtÞ dt

where Z

tf

TðtÞ dt 0

corresponds to the area under the roasting curve (areatf), which can be estimated using the trapezoidal rule for numerical integration. We have, then Δmexpt ¼ a½tf  þ b  areatf

ð1Þ

where Wbr and War are the weights before and after roasting, respectively. Water Content. To express the amount of CGA on a dry basis (db), the water content of freshly ground green and roasted coffee beans was determined gravimetrically according to the AOAC method (23). Chlorogenic Acids Analysis. Chlorogenic acids in the green and roasted coffee samples were analyzed in duplicate using liquid chromatography techniques according to the methods described by Farah et al. (7) and Perrone et al. (14). A total of nine CGA compounds were quantified in all samples: 3-, 4-, and 5-CQA, 3-, 4-, and 5-FQA, and 3,4-, 3,5-, and 4,5diCQA. The sum of these compounds, hereafter referred as total CGA, was used for modeling CGA degradation. Weight Loss Modeling. The weight loss models were developed using the roasting curves and weight loss measurements of the coffee samples, assuming that the weight loss rate was either independent or linearly dependent on roasting temperature. Model 1: Weight Loss Rate Independent of Temperature. The first developed model hypothesizes that the weight loss rate is independent of

ð7Þ

0

ð8Þ

which leads to an expression for the objective function f ða;bÞ ¼

i¼n expt X

f½ðtf Þa þ areatf  b - Δmg2

ð9Þ

i¼1

which, after minimization with respect to a and b, leads to a set of two equations 2 3 2 3 i¼n i¼n i¼n expt expt expt X X X 4 ðtf Þ2 5a þ 4 areatf ðtf Þ5b ¼ Δmðtf Þ ðtf Þ ð10Þ i¼1

2

i¼n expt X

4

i¼1

i¼1

3

2

i¼n expt X

areatf ðtf Þ5a þ 4

i¼1

i¼1

3 ðareatf Þ2 5b ¼

i¼n expt X

Δmðtf Þ  areatf

ð11Þ

i¼1

which can be numerically solved to obtain the values of a and b. Using eq 8, the theoretical weight loss can be finally obtained.

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Perrone et al. Table 2. Experimental and Calculated Weight Loss Values for the C. arabica Sample Using Models Assuming That the Weight Loss Rate Was Independent (Model 1) or Linearly Dependent (Model 2) on the Roasting Temperaturea calculated wt loss (%) roasting time (min), tR

experimental wt loss (%), Δm(tf )

model 1

relative error (%)

model 2

relative error (%)

170 °C 4 5* 6* 7 8 9

Figure 1. Typical time-temperature roasting curves, represented by those obtained when coffee samples were roasted at a set temperature of 180 °C for 4, 5, 6, 7, 8, or 9 min, followed by a fixed 4 min air-cooling period. Y-axis shows the air temperature inside the roasting chamber. Table 1. Experimental and Calculated Weight Loss Values for the C. canephora Sample Using Models Assuming That the Weight Loss Rate Was Independent (Model 1) or Linearly Dependent (Model 2) on the Roasting Temperaturea calculated wt loss (%) roasting time (min), tR

experimental wt loss (%), Δm(tf )

model 1

relative error (%)

model 2

relative error (%)

-4.0 -2.1 1.4 -1.3 4.4 5.2

12.03 13.25 14.50 15.59 16.89 18.01

0.3 0.2 2.3 -2.7 2.1 1.3

12.63 14.15 15.72 17.25 18.43 19.15

11.99 13.22 14.18 16.03 16.54 17.78

11.51 12.94 14.38 15.82 17.26 18.70

13.00 14.47 16.14 16.77 18.42 18.98

12.30 13.84 15.37 16.91 18.45 19.98

-5.4 -4.4 -4.8 0.8 0.1 5.3

13.44 14.74 15.88 16.94 18.10 19.29

3.4 1.8 -1.6 1.0 -1.7 1.7

0.7 -2.3 -2.1 -4.2 -0.7 5.8

14.03 15.28 16.59 17.82 19.02 20.20

9.1 2.5 0.3 -4.0 -2.8 1.7

-4.5 0.8 4.3 1.3 -1.9 2.6

20.43 22.37 24.59 26.77 29.04 31.34

0.0 2.8 5.3 1.2 -2.6 1.5

190 °C 4* 5 6 7 8* 9

12.85 14.90 16.53 18.57 19.56 19.87

12.94 14.56 16.18 17.80 19.41 21.03 200 °C

4 5* 6* 7 8 9

20.42 21.76 23.36 26.46 29.82 30.89

19.50 21.94 24.37 26.81 29.25 31.69

12.80 14.12 15.53 16.82 18.22 19.60

1.3 -0.2 -1.2 -2.5 -1.1 2.4

4 5 6* 7 8* 9

13.33 15.41 16.30 18.10 18.77 19.83

12.91 14.53 16.14 17.76 19.37 20.99

-3.1 -5.7 -1.0 -1.9 3.2 5.8

13.76 15.14 16.35 17.62 18.99 20.16

3.3 -1.8 0.3 -2.7 1.2 1.6

-3.8 -8.8 -2.1 -4.5 1.8 3.5

14.03 15.40 16.78 18.33 19.69 20.96

2.2 -5.5 -0.6 -3.7 1.1 1.0

1.6% -1.6% -1.8% -0.9% 1.4% 2.6%

17.20 19.38 21.56 23.73 25.90 28.08

1.3% -1.7% -1.8% -0.9% 1.5% 2.8%

190 °C 4 5* 6* 7 8 9

13.73 16.30 16.88 19.03 19.47 20.75

13.21 14.87 16.52 18.17 19.82 21.47 200 °C

180 °C 4* 5 6 7* 8 9

-3.2 -2.8 -2.8 -2.6 -0.5 3.7

180 °C

170 °C 4 5 6* 7 8 9*

12.22 13.75 15.28 16.81 18.33 19.86

a Coffee samples marked with an asterisk comprised the validation database of the models.

In a similar spirit, more complicated models were tested, such as a quadratic temperature dependence model. However, the use of such models did not improve prediction of the weight loss during roasting.

4 5* 6 7 8 9*

16.98 19.72 21.95 23.94 25.53 27.32

17.25 19.41 21.56 23.72 25.88 28.03

a Coffee samples marked with an asterisk comprised the validation database of the models.

Kinetic Calculations for CGA Degradation. The kinetic model proposed in this study (eq 13) was chosen because of the balance between its simplicity and the good fitting of experimental data it provided. We assumed that the kinetic parameters followed the Arrhenius law. A general reaction rate expression for the degradation kinetics can be written as (24-26) - d½C=dt ¼ k½Cm

ð12Þ

where [C] is the quantitative value of the component under consideration, k is the reaction rate constant, and m is the order of the reaction. Degradation of CGA has been reported to follow first-order kinetics (27), of which the integrated rate equation can be expressed as lnð½Ct =½C0 Þ ¼ - kT t

ð13Þ

where [C]0 and [C]t are the concentrations of CGA at time zero and time t (min), respectively, and kT is the temperature-dependent degradation rate constant, defined by the Arrhenius equation kT ¼ A0 expð- Ea =RTÞ

ð14Þ

where Ea is the activation energy of the reaction (kJ mol-1), R is the universal gas constant (8.3145 J mol-1 K-1), T is the absolute temperature (K), and the pre-exponential factor constant A0 is the frequency factor (min-1).

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Table 3. Total CGA Content in Green and Roasted Coffee Samples Used To Compute the Degradation Modela chlorogenic acid content (g/100 g dwb) temp (°C)

time (min)

C. canephora

C. arabica

green

0

10162.2 ( 76.4

8277.4 ( 121.5

170

4 5 6 7 8 9

4942.5 ( 50.5 3741.5 ( 1.3* 2516.3 ( 54.9* 1147.5 ( 18.9 1032.4 ( 2.9 606.1 ( 19.2

3931.9 ( 242.7* 2566.1 ( 8.4 2285.9 ( 18.8 1374.7 ( 46.2* 1175.0 ( 29.6 944.1 ( 23.4

180

4 5 6 7 8 9

4595.3 ( 284.1 2945.3 ( 3.0 1780.8 ( 6.3* 1088.2 ( 15.1 493.8 ( 7.2 507.8 ( 50.8*

4036.2 ( 21.9 3002.7 ( 39.2 1911.4 ( 85.4* 1675.4 ( 0.7 1206.0 ( 12.5* 840.0 ( 6.7

190

4 5 6 7 8 9

3703.0 ( 21.5* 2559.0 ( 7.7 1088.3 ( 3.3 579.5 ( 29.6 371.3 ( 5.0* 162.9 ( 2.6

3035.7 ( 20.8 2088.1 ( 8.2 1378.6 ( 10.1 1186.1 ( 17.6* 771.7 ( 17.6* 460.8 ( 0.3

200

4 5 6 7 8 9

1524.7 ( 63.4 183.9 ( 0.4* 123.9 ( 0.9 30.1 ( 0.3* 19.4 ( 1.7 13.0 ( 0.2

1483.7 ( 16.1* 666.4 ( 1.2* 331.2 ( 0.3 154.2 ( 0.5 84.9 ( 1.8 57.0 ( 0.8

Figure 2. Comparison of experimental and calculated weight losses (%) in roasted coffee samples using models assuming that the weight loss rate was independent (model 1) or linearly dependent (model 2) on the roasting temperature. RESULTS AND DISCUSSION

Weight Loss Modeling. Coffee samples were roasted at 170, 180, 190, or 200 °C for 4, 5, 6, 7, 8, or 9 min. Air temperature inside the roasting chamber was monitored at 1 min intervals, yielding time-temperature roasting curves. Typical roasting curves obtained for both samples with the set temperature of 180 °C are depicted in Figure 1. The experimental and calculated weight loss values for the C. canephora and C. arabica coffee samples using the two models proposed are presented in Tables 1 and 2, respectively. As a consequence of the differences in their chemical composition and cell wall structure (28), different model parameters were determined to predict weight loss for C. arabica and C. canephora beans. Satisfactory correlations (r > 0.99) between calculated and experimental weight losses were obtained using both models (Figure 2). Residual analysis showed that residues were normally distributed and homoscedastic. Considering both samples, the average relative error was 2.9% in the case of model 1 and 2.0% for model 2. The quadratic temperature dependence model of the weight loss rate, not presented here, led to an average relative error of 1.7% Although the tested models showed similar efficiency in terms of correlation between experimental and calculated values and of relative error, the results clearly suggest the adoption of the quadratic temperature dependence model, but because of simplicity, good prediction, and the fact that knowledge of instant temperature is not needed, model 1 may be preferred. This means that once a series of roasting curves are obtained at certain process parameters (set temperature for a specific roasting equipment, roasting batch mass, and species), the model parameters proposed here may be calculated. Then, future predictions of weight loss could be made solely on the basis of the roasting time, with no need to monitor the instantaneous temperature inside the roaster’s chamber during the process. Chlorogenic Acids Degradation Kinetic Models. Table 3 shows the concentrations of total CGA in green and roasted coffee samples used to compute the degradation kinetic models. Total CGA contents in green C. canephora and C. arabica were 10.16 and 8.28 g/100 g dwb, respectively, which are in agreement with various studies in the literature (13-16, 20, 21, 29). From the CGA results, it was evident that samples roasted at higher roasting temperatures presented more pronounced CGA losses, as expected. Using linear regression analysis, the degradation data were analyzed using the standard integrated rate equation to determine

a CGA values are presented as the mean ( SD of two replicates of analysis. Coffee samples marked with an asterisk comprised the validation database of the models.

the overall order and rate constant for the degradation reaction. A correlation coefficient r > 0.98 in all samples confirmed that CGA degradation followed first-order reaction at all temperatures tested, as expected from previous papers in the literature (27). Figure 3 shows the first-order plots of CGA degradation in C. canephora and C. arabica samples at 170, 180, 190, and 200 °C. The half-life time (t1/2), required for CGA to degrade to 50% of its original value, was calculated from the rate constant kT, as t1/2 = ln 2/kT. The average rate constants for CGA degradation in C. arabica and C. canephora, respectively, increased from 0.2665 and 0.4116 min-1 at 170 °C to 0.5875 and 0.9691 min-1 at 200 °C. A corresponding decrease in half-life, from 2.60 and 1.68 min at 170 °C to 1.18 and 0.72 min at 200 °C, was observed. Figure 4 shows the Arrhenius plot for total CGA degradation in C. canephora and C. arabica. The linear nature of the obtained plots (r > 0.96) indicates that thermal degradation of total CGA conforms to the Arrhenius equation (eq 14). Apparent activation energy Ea (kJ mol-1) was calculated as a product of the gas constant R (8.3145 J mol-1 K-1) and the slope of the graph obtained by plotting lnk versus 1/T. The apparent activation energies for CGA thermal degradation in C. arabica and C. canephora were found to be 44.4 and 48.4 kJ mol-1, respectively. Using a tubular reactor operated under approximately isothermal conditions, Sharma et al. (27) reported an apparent activation energy of 79 kJ mol-1 for 5-CQA pyrolysis, which is of the same magnitude as the value calculated in this study. The slightly higher activation energy for CGA degradation in C. canephora compared to C. arabica could be explained by intrinsic differences

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Perrone et al.

Figure 3. First-order plots of total CGA degradation in coffee samples at 170, 180, 190, and 200 °C.

Figure 4. Arrhenius plot for total CGA degradation in C. arabica and C. robusta.

in the cell wall structures of both species (15, 16, 28). The frequency factors A0 (min-1) were calculated as the exponential of the intercept of the Arrhenius plot at 1/T = 0 and found to be 4.27  104 and 2.10  105 min-1 for C. arabica and C. canephora, respectively. Taken together, Ea and A0 indicate the number of successful collisions that have enough kinetic energy to lead the reaction of CGA degradation. To predict the degradation of total CGA during coffee roasting, eq 14 was used together with the determined rate constants for CGA degradation, kT. A strong correlation (r=0.98) between experimental and calculated values was obtained (Figure 5). Residual analysis showed that residues were normally distributed and homoscedastic. Even though an average relative error of 16.5% was found between experimental and calculated values, this was mostly attributed to the dark-roasted samples. In

these samples, very low amounts of total CGA were found (from 0.184 to 0.013 g/100 g dwb), causing higher deviations for calculated values. However, when these deviations are translated into absolute values, their significance is irrelevant. When only mild roasting conditions were considered, the proposed model predictions were shown to be good. Prediction of CGA content for samples with contents of >0.2 g/100 g dwb, for example, showed an acceptable relative error, on average, 10.6%. Considering coffee samples that presented weight losses of up to 18% (moderately light to moderately dark, depending on species), which are the most relevant roasting degrees for the coffee industry, an average relative error of 12.9% was found. This relative error is in line with values reported by other modeling studies found in the literature (25, 26). When modeling the degradation of β-N-oxalylL-2,3-diaminopropionic acid, a nonprotein neurotoxic amino acid in grass pea flour, Tarade et al. (26) reported an average relative error of 18.4% using first-order Arrhenius-compliant kinetic models. In this way, the proposed model in the present study is suitable for the prediction of total CGA degradation during coffee roasting. Although only one sample of each coffee species was used to generate the present CGA degradation models, on the basis of our previous experience with CGA loss during roasting, it is possible to say that, most probably, model predictions will be valid for different coffee cultivars of the same species, given that the same roasting conditions are maintained. Actually, the proposed model approach was applied to data from previous independent studies (1, 7, 14-16, 20-22), which comprised seven C. arabica and three C. canephora cultivars, and we observed that weight loss and CGA degradation of all cultivars of a single species could be predicted by its respective model. In conclusion, coffee weight loss during roasting was successfully modeled independently of the instant temperature during the process. CGA degradation during coffee roasting followed first-order reaction kinetics. A mathematical model was developed,

Article

Figure 5. Comparison of experimental and calculated total CGA content (g/100 g dwb) in roasted coffee samples using a kinetic model based on a first-order reaction rate and the Arrhenius law.

using the apparent activation energy of CGA degradation and the temperature-dependent reaction rate, which complied with the Arrhenius equation. This model was capable of predicting the thermally induced degradation of CGA, especially for light to moderately dark-roasted coffee samples. Altogether, the proposed models may become important predictive tools in the coffee industry. ACKNOWLEDGMENT

We thank Jose´ Mauro Costa Monteiro for supplying coffee samples and Izaura Nascimento for assistance with coffee roasting experiments and CGA analysis. LITERATURE CITED (1) Farah, A.; Monteiro, M. C.; Calado, V.; Franca, A.; Trugo, L. C. Correlation between cup quality and chemical attributes of Brazilian coffee. Food Chem. 2006, 98, 373-380. (2) Mwithiga, G.; Jindal, V. K. Physical changes during coffee roasting in rotary conduction-type heating units. J. Food Process. Eng. 2003, 26, 543-558. (3) Clarke, R. J. Coffee: roast and ground. In Encyclopedia of Food Sciences and Nutrition, 1st ed.; Caballero, B., Trugo, L. C., Finglas, P. M., Eds.; Academic Press: Oxford, U.K., 2003; Vol. 7, 1487 pp. (4) Dutra, E. R.; Oliveira, L. S.; Franca, A. S.; Ferraz, V. P.; Afonso, R. J. C. F. A preliminary study on the feasibility of using the composition of coffee roasting exhaust gas for the determination of the degree of roast. J. Food Eng. 2001, 47, 241-246. (5) Herna´ndez, J. A.; Heyd, B.; Irles, C.; Valdovinos, B.; Trystram, G. Analysis of the heat and mass transfer during coffee batch roasting. J. Food Eng. 2007, 78, 1141-1148. (6) Dorfner, R.; Ferge, T.; Yeretzian, C.; Kettrup, A.; Zimmermann, R. Laser mass spectroscopy as on-line sensor for industrial process analysis: process control of coffee roasting. Anal. Chem. 2004, 76, 1386-1402. (7) Farah, A.; de Paulis, T.; Trugo, L. C.; Martin, P. R. Effect of roasting on the formation of chlorogenic acid lactones in coffee. J. Agric. Food Chem. 2005, 53, 1505-1513. (8) Stennert, A.; Maier, H. G. Trigonelline in coffee. III. Calculation of the degree of roast by the trigonelline/nicotinic acid ratio. New gas-chromatographic method for nicotinic acid. Z. Lebensm.Unters. Forsch. A 1996, 202, 45-47. (9) Oliveira, S. D.; Franca, A. S.; Glo´ria, M. B. A.; Borges, M. L. A. The effect of roasting on the presence of bioactive amines in coffees of different qualities. Food Chem. 2005, 90, 287-291. (10) Sua´rez-Quiroz, M.; de Louise, B.; Gonzalez-Rios, O.; Barel, M.; Guyot, B.; Schorr-Galindo, S.; Guiraud, J. The impact of roasting on the ochratoxin A content of coffee. Int. J. Food Sci. Technol. 2005, 40, 605-611.

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